Operando decoding of chemical and thermal events in commercial Na(Li)-ion cells via optical sensors

• Published in: Nature energy Vol. 5; no. 9; pp. 674 - 683
• Main Authors: Huang, Jiaqiang, Albero Blanquer, Laura, Bonefacino, Julien, Logan, E. R., Alves Dalla Corte, Daniel, Delacourt, Charles, Gallant, Betar M., Boles, Steven T., Dahn, J. R., Tam, Hwa-Yaw, Tarascon, Jean-Marie
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 01.09.2020; Nature Publishing Group
• Subjects: 639/4077/4079/891; 639/638/11/511; 639/638/440/951; 639/638/675; Additives; Analytical chemistry; Bragg gratings; Calorimetry; Chemical engineering; Chemical Sciences; Chemical sensors; Economics and Management; Electrolytes; Electrolytic cells; Energy; Energy Policy; Energy Storage; Energy Systems; Engineering Sciences; Management systems; Materials; Optical fibers; Optical measuring instruments; Parameterization; Product safety; Reliability; Renewable and Green Energy; Sensors; Solid electrolytes; Thermal analysis; Thermal management; Tracking
• ISSN: 2058-7546; 2058-7546
• DOI: 10.1038/s41560-020-0665-y

Monitoring the dynamic chemical and thermal state of a cell during operation is crucial to making meaningful advancements in battery technology as safety and reliability cannot be compromised. Here we demonstrate the feasibility of incorporating optical fibre Bragg grating sensors into commercial 18650 cells. By adjusting fibre morphologies, wavelength changes associated with both temperature and pressure are decoupled with high accuracy, which allows tracking of chemical events such as solid electrolyte interphase formation and structural evolution. We also demonstrate how multiple sensors are used to determine the heat generated by the cell without resorting to microcalorimetry. Unlike with conventional isothermal calorimetry, the cell’s heat capacity contribution is readily assessed, allowing for full parametrization of the thermal model. Collectively, these findings offer a scalable solution for screening electrolyte additives, rapidly identifying the best formation processes of commercial cells and designing battery thermal management systems with enhanced safety. Tracking a battery’s chemical and thermal states during operation offers important information on its reliability and lifetime. Here the authors develop optical fibre sensors and decouple temperature and pressure variations in the measurements inside of batteries, allowing chemical and thermal events to be monitored with high accuracy.